Global ETD Search

61	"Hepatite colestática associada ao vírus da hepatite C pós-transplante hepático: estudo virológico, histopatológico e imuno-histoquímico" / Severe recurrent cholestatic hepatitis after liver transplantation : virological, histological and immuno-histochemical evaluation Pessôa, Mário Guimarães 20 February 2004 (has links) A evolução da recorrência da hepatie C pós-transplante hepático pode ter um curso bastante variável. Raramente a doença pode progredir para uma forma conhecida como hepatite recorrente colestática grave, cuja patogenia ainda não é bem conhecida. Nós estudamos nesse trabalho alguns aspectos virológicos, histológicos e imunohistoquímicos de seis pacientes com essa forma rara de recorrência da doença, tendo como comparação um grupo pareado de seis pacientes transplantados com a forma leve de hepatite C recorrente, e como controle imunocompetente, cinco pacientes não transplantados com hepatite crônica pelo vírus C. Foram avaliados como possíveis fatores preditivos de gravidade da progressão da recorrência: viremia do VHC, evolução de quasispécies, parâmetros histopatológicos, e imunoreatividade para o antígeno core do VHC. / Following liver transplantation (OLT) HCV-related disease severity is highly variable, with a minority of cases progressing to an extremely severe form of cholestatic hepatitis, in which the pathogenesis is not yet understood. We aim to compare virological, histological and immunohistological changes in patients developing mild and severe post-OLT HCV recurrence. Twelve patients with recurrent HCV infection were studied (6 with severe and 6 with mild disease). Five HCV-infected immunocompetent patients were used as controls. We looked at viral load, quasispecies evolution of HCV, several histological parameters and immuno-reactivity of core antigens at three time-points (pre-OLT, early post-OLT and late post-OLT) as predictors of severity of recurrence post-OLT. Hepatite C crônica/etiologia Hepatite C crônica/fisiopatologia Hepatite C crônica/virologia Hepatitis C chronic/etiology Hepatitis C chronic/physiopathology Hepatitis C chronic/virology Liver transplantation/pathology Replicação viral Transplante de fígado/patologia Virus replication
62	Vliv proteinu HBx viru hepatitidy B na aktivaci MEK1/2-ERK signalizace a inhibici IFN typu I v hepatocelulární linii Huh7 / Effect of HBV protein HBx on activation of MEK1/2 signaling and inhibition of type I IFN in hepatoma cell line Huh7 Berehovska, Olena January 2019 (has links) Hepatitis B virus (HBV) infection is one of the major causes of chronic and cancerous liver disease. Elimination of HBV from chronically infected patients by recombinant interferon α (IFNα) monotherapy shows that the mechanisms of the innate immunity play an important role in suppressing viral infection. However, the mechanisms of recognition of the HBV genome and its escape from the mechanisms of natural immunity are still little known. One of the principal factors enabling the virus to escape from cellular restriction mechanisms is the HBx viral protein. HBx is a 154 amino acid pleiotropic multifunctional protein affecting transcription, signal transduction, cell cycle, protein degradation, apoptosis, and chromosomal stability in the host cell. Previous results from our laboratory have shown that activation of the MEK1/2-ERK signaling pathway in plasmacytoid dendritic cells leads to inhibition of IFNα production. The aim of my work was to determine whether HBx activates the MEK1/2-ERK pathway and thus inhibits IFN type I production also in hepatocytes. For this purpose, I monitored HBx production in the Huh7 hepatoma cell line by transfecting the bicistronic plasmid pHBx- IRES-EGFP and Western blotting. Using the same method, I monitored activation of the MEK1/2-ERK signaling pathway by ERK...
63	Modelling genetic regulatory networks: a new model for circadian rhythms in Drosophila and investigation of genetic noise in a viral infection process Xie, Zhi January 2007 (has links) In spite of remarkable progress in molecular biology, our understanding of the dynamics and functions of intra- and inter-cellular biological networks has been hampered by their complexity. Kinetics modelling, an important type of mathematical modelling, provides a rigorous and reliable way to reveal the complexity of biological networks. In this thesis, two genetic regulatory networks have been investigated via kinetic models. In the first part of the study, a model is developed to represent the transcriptional regulatory network essential for the circadian rhythms in Drosophila. The model incorporates the transcriptional feedback loops revealed so far in the network of the circadian clock (PER/TIM and VRI/PDP1 loops). Conventional Hill functions are not used to describe the regulation of genes, instead the explicit reactions of binding and unbinding processes of transcription factors to promoters are modelled. The model is described by a set of ordinary differential equations and the parameters are estimated from the in vitro experimental data of the clocks components. The simulation results show that the model reproduces sustained circadian oscillations in mRNA and protein concentrations that are in agreement with experimental observations. It also simulates the entrainment by light-dark cycles, the disappearance of the rhythmicity in constant light and the shape of phase response curves resembling that of experimental results. The model is robust over a wide range of parameter variations. In addition, the simulated E-box mutation, perS and perL mutants are similar to that observed in the experiments. The deficiency between the simulated mRNA levels and experimental observations in per01, tim01 and clkJrk mutants suggests some differences in the model from reality. Finally, a possible function of VRI/PDP1 loops is proposed to increase the robustness of the clock. In the second part of the study, the sources of intrinsic noise and the influence of extrinsic noise are investigated on an intracellular viral infection system. The contribution of the intrinsic noise from each reaction is measured by means of a special form of stochastic differential equation, the chemical Langevin equation. The intrinsic noise of the system is the linear sum of the noise in each of the reactions. The intrinsic noise arises mainly from the degradation of mRNA and the transcription processes. Then, the effects of extrinsic noise are studied by means of a general form of stochastic differential equation. It is found that the noise of the viral components grows logarithmically with increasing noise intensities. The system is most susceptible to noise in the virus assembly process. A high level of noise in this process can even inhibit the replication of the viruses. In summary, the success of this thesis demonstrates the usefulness of models for interpreting experimental data, developing hypotheses, as well as for understanding the design principles of genetic regulatory networks. systems biology genetic regulatory networks mathematical molecular modelling kinetic modelling Hill function stochastic modelling stochastic differential equations chemical Langevin equation oscillations circadian clock circadian rhythms Drosophila intrinsic noise extrinsic noise viral infection virus replication
64	Identification of a new cell line permissive to porcine reproductive and resporatory syndrome virus replication Jian-Jun, Jia 08 1900 (has links) Le syndrome reproducteur et respiratoire porcin (SRRP) est une des maladies les plus dévastatrices économiquement pour l'industrie mondiale du porc. L'agent étiologique du SRRP est le virus du SRRP (VSRRP) lequel est connu pour avoir une spécificité d'hôte très restreinte et pour sa transmission par voie aerosol. Les antigènes et les ARN du VSRRP ont été trouvés dans des cellules épithéliales du tractus respiratoire de porcs infectés par le virus. L’interaction entre les macrophages alvéolaires porcins (PAMs) et le VSRRP a été démontrée comme jouant un rôle important dans l’infection causée par le virus. Malgré cela, l’interaction prenant place entre les cellules épithéliales du tractus respiratoire porcin et le virus ne devrait pas être négligée. Jusqu’à présent, la réplication du VSRRP in vitro dans des cellules épithéliales du tractus respiratoire porcin n’a pas été conduite avec succès et les tentatives pour le faire ont échoué. Une nouvelle lignée de cellules épithéliales de poumon de porc (SJPL) est maintenant disponible et sera utilisée dans cette étude afin de déterminer si elle est permissive à la réplication du VSRRP et si elle peut être un modèle approprié pour l’étude de la pathogénèse virale du VSRRP. L’expérimentation a démontré que cette nouvelle lignée cellulaire était permissive à l’infection et à la réplication du VSRRP. Afin de corroborer ces résultats, la cinétique de réplication du virus à été effectuée avec les cellules MARC-145 et SJPL. Aucune différence significative dans la production virale totale n’a été trouvée entre les deux lignées cellulaires. Les cellules SJPL ont permis la réplication de plusieurs souches Nord-Américaines du VSRRP, quoiqu’elles sont légèrement moins efficaces que les cellules MARC-145 pour l’isolement du virus. De plus, les cellules SJPL sont phénotypiquement différentes des cellules MARC-145. Plus précisément, les cellules SJPL sont plus sensibles à l’activation par le VSRRP des pro-caspases 3/7 et plusieurs inducteurs apoptotiques. Elles ont également montré de 8 à 16 fois plus de sensibilité à l’effet antiviral causé par l’IFN-α sur la réplication du virus contrairement aux cellules MARC-145. Ces résultats démontrent que les cellules SJPL pourraient représenter un substitut intéressant aux cellules MARC-145 pour la production d’antigènes pour un vaccin anti-VSRRP. Également, dû à leurs origines (poumon de l’hôte naturel), elles pourraient s’avérer être un modèle in vitro plus approprié pour l’étude de la pathogénèse du VSRRP. / Porcine reproductive and respiratory syndrome (PRRS) is one of the most economically devastating diseases for the pig industry worldwide. The etiological agent of PRRS is the PRRS virus (PRRSV), which is known to have a very restricted host specifity and to be airborne transmitted. PRRSV RNAs and antigens were found in epithelial cells of the respiratory tract of swine in PRRSV-infected pigs. Even if the interaction between porcine alveolar macrophages (PAMs) and PRRSV plays an important role in the PRRSV infection, the role of the interaction between epithelial cells of the swine respiratory tract and PRRSV should not been neglected. However, no epithelial cells of the swine respiratory tract have been demonstrated to allow PRRSV replication in vitro and attempts to generate such a cell line have failed. The goal of this study is to determine whether epithelial cells of the swine respiratory tract are permissive to PRRSV replication and are a suitable model for studying the viral pathogenesis of PRRSV. We have discovered that the SJPL cell line, an epithelial cell line of the respiratory tract of swine, is permissive to PRRSV infection and replication. To corroborate these results, PRRSV replication kinetics were evaluated in a subclone of the African green monkey kidney MA104 cells (MARC-145), which has been known to be fully permissive to PRRSV infection and replication, and in SJPL cells. No significant difference was found between the two cell lines for overall viral production. Moreover, the SJPL cells were able to permit the replication of several PRRSV North-American strains but they were slightly less efficient for virus isolation than MARC-145 cells. In addition, SJPL is phenotypically different from MARC-145. Specifically, the SJPL cells were more sensitive to procaspases 3/7 activation by PRRSV and several apoptotic inducers compared to MARC-145 cells. In addition, the SJPL cells showed 8 to 16 times more sensitivity to the antiviral effect of IFN-α against PRRSV replication than MARC-145 cells. Altogether, the SJPL cells could be an interesting substitute to MARC-145 cells for PRRSV vaccine antigen production, and could be a more relevant in vitro model, because of their origin (lung of the natural host), to study the pathogenesis of PRRSV. VSRRP Cellule épithéliale de poumon de porc SJPL Réplication virale Cellule permissive PRRSV Porcine lung epithelial cell SJPL Virus replication Cell permissiveness
65	"Hepatite colestática associada ao vírus da hepatite C pós-transplante hepático: estudo virológico, histopatológico e imuno-histoquímico" / Severe recurrent cholestatic hepatitis after liver transplantation : virological, histological and immuno-histochemical evaluation Mário Guimarães Pessôa 20 February 2004 (has links) A evolução da recorrência da hepatie C pós-transplante hepático pode ter um curso bastante variável. Raramente a doença pode progredir para uma forma conhecida como hepatite recorrente colestática grave, cuja patogenia ainda não é bem conhecida. Nós estudamos nesse trabalho alguns aspectos virológicos, histológicos e imunohistoquímicos de seis pacientes com essa forma rara de recorrência da doença, tendo como comparação um grupo pareado de seis pacientes transplantados com a forma leve de hepatite C recorrente, e como controle imunocompetente, cinco pacientes não transplantados com hepatite crônica pelo vírus C. Foram avaliados como possíveis fatores preditivos de gravidade da progressão da recorrência: viremia do VHC, evolução de quasispécies, parâmetros histopatológicos, e imunoreatividade para o antígeno core do VHC. / Following liver transplantation (OLT) HCV-related disease severity is highly variable, with a minority of cases progressing to an extremely severe form of cholestatic hepatitis, in which the pathogenesis is not yet understood. We aim to compare virological, histological and immunohistological changes in patients developing mild and severe post-OLT HCV recurrence. Twelve patients with recurrent HCV infection were studied (6 with severe and 6 with mild disease). Five HCV-infected immunocompetent patients were used as controls. We looked at viral load, quasispecies evolution of HCV, several histological parameters and immuno-reactivity of core antigens at three time-points (pre-OLT, early post-OLT and late post-OLT) as predictors of severity of recurrence post-OLT. Hepatite C crônica/etiologia Hepatite C crônica/fisiopatologia Hepatite C crônica/virologia Replicação viral Transplante de fígado/patologia Hepatitis C chronic/etiology Hepatitis C chronic/physiopathology Hepatitis C chronic/virology Liver transplantation/pathology Virus replication
66	Unravelling The Regulators Of Translation And Replication Of Hepatitis C Virus Ray, Upasana January 2011 (has links) (PDF) Unravelling the regulators of translation and replication of Hepatitis C virus Hepatitis C virus (HCV) is a positive sense, single stranded RNA virus belonging to the genus Hepacivirus and the family Flaviviridae. It infects human liver cells predominantly. Although, the treatment with α interferon and ribavirin can control HCV in some cases, they fail to achieve sustained virological response in others, thus emphasizing the need of novel therapeutic targets. The viral genome is 9.6 kb long consisting of a 5’ untranslated region (5’UTR), a long open reading frame (ORF) that encodes the viral proteins and the 3’ untranslated region (3’UTR). The 5’UTR contains a cis acting element, the internal ribosome entry site (IRES) that mediates the internal initiation of translation. The HCV 5’UTR is highly structured and consists of four major stem-loops (SL) and a pseudoknot structure. HCV proteins are synthesized by the IRES mediated translation of the viral RNA, which is the initial obligatory step after infection. The viral proteins are synthesized in the form of a long continuous chain of proteins, the polyprotein, which is then processed by the host cell and the viral proteases. Once viral proteins are synthesized sufficiently, the viral RNA is replicated. However the mechanism of switch from translation to viral RNA replication is not well understood. Several host proteins as well as the viral proteins help in the completion of various steps in the HCV life cycle. In this thesis, the role of two such factors in HCV RNA translation and replication has been characterized and exploited to develop anti-HCV peptides. The HCV proteins are categorized into two major classes based on the functions broadly: the non structural and the structural proteins. HCV NS3 protein (one of the viral non structural proteins) plays a central role in viral polyprotein processing and RNA replication. In the first part of the thesis, it has been demonstrated that the NS3 protease (NS3pro) domain alone can specifically bind to HCV-IRES RNA, predominantly in the SLIV region. The cleavage activity of the NS3 protease domain is reduced upon HCV-RNA binding owing to the participation of the catalytic triad residue (Ser 139) in this RNA protein interaction. More importantly, NS3pro binding to the SLIV region hinders the interaction of La protein, a cellular IRES-trans acting factor required for HCV IRES-mediated translation, thus resulting in the inhibition of HCV-IRES activity. Moreover excess La protein could rescue the inhibition caused by the NS3 protease. Additionally it was observed that the NS3 protease and human La protein could out-compete each other for binding to the HCV SL IV region indicating that these two proteins share the binding region near the initiator AUG which was further confirmed using RNase T1 foot printing assay. Although an over expression of NS3pro as well as the full length NS3 protein decreased the level of HCV IRES mediated translation in the cells, replication of HCV RNA was enhanced significantly. These observations suggested that the NS3pro binding to HCV IRES reduces translation in favour of RNA replication. The competition between the host factor (La) and the viral protein (NS3) for binding to HCV IRES might contribute in the regulation of the molecular switch from translation to replication of HCV. In the second part the interaction of NS3 protease and HCV IRES has been elucidated in detail and the insights obtained were used to target HCV RNA function. Computational approach was used to predict the putative amino acid residues within the protease that might be involved in the interaction with the HCV IRES. Based on the predictions a 30-mer peptide (NS3proC-30) was designed from the RNA binding region. This peptide retained the RNA binding ability and also inhibited IRES mediated translation. The NS3proC-30 peptide was further shortened to 15-mer length (NS3proC-C15) and demonstrated ex vivo its ability to inhibit translation as well as replication. Additionally, its activity was tested in vivo in a mice model by encapsulating the peptide in Sendai virus based virosome followed by preferential delivery in mice liver. This virosome derived from Sendai virus F protein has terminal galactose moiety that interacts with the asialoglycoprotein receptor on the hepatocytes leading to membrane fusion and release of contents inside the cell. Results suggested that this peptide can be used as a potent anti-HCV agent. It has been shown earlier from our laboratory, that La protein interacts with HCVIRES near initiator AUG at GCAC motif by its central RNA recognition motif, the RRM2 (residues 112-184). A 24 mer peptide derived from this RRM2 of La (LaR2C) retained RNA binding ability and inhibited HCV RNA translation. NMR spectroscopy of the HCV-IRES bound peptide complex revealed putative contact points, mutations at which showed reduced RNA binding and translation inhibitory activity. The residues responsible for RNA recognition were found to form a turn in the RRM2 structure. A 7-mer peptide (LaR2C-N7) comprising this turn showed significant translation inhibitory activity. The bound structure of the peptide inferred from transferred NOE (Nuclear Overhauser Effect) experiments suggested it to be a βturn. Interestingly, addition of hexa-arginine tag enabled the peptide to enter Huh7 cells and showed inhibition HCV-IRES function. More importantly, the peptide significantly inhibited replication of HCVRNA. Smaller forms of this peptide however failed to show significant inhibition of HCV RNA functions suggesting that the 7-mer peptide as the smallest but efficient anti-HCV peptide from the second RNA recognition motif of the human La protein. Further, combinations of the LaR2C-N7 and NS3proC-C15 peptide showed better inhibitory activity. Both the peptides were found to be interacting at similar regions of SLIV around the initiator AUG. The two approaches have the potential to block the HCV RNA-directed translation by targeting the host factor and a viral protein, and thus can be tried in combination as a multi drug approach to combat HCV infection. Taken together, the study reveals important insights about the complex regulation of the HCV RNA translation and replication by the host protein La and viral NS3 protein. The interaction of the NS3 protein with the SLIV of HCV IRES leads to dislodging of the human La protein to inhibit the translation in favour of the RNA replication. These two proteins thus act as the regulators of the translation and the replication of viral RNA. The peptides derived from these regulators in turn regulate the functions of these proteins and inhibit the HCV RNA functions. Hepatitis C Virus (HCV) Hepatitis C Virus - Replication HCV-NS3 Protein Non-structural Protein 3 Human La Protein HCV IRES NS3 Protease Hep C Viral Switch Hepatitis C Viral RNA NS3 Protein Virology
67	Mutations in the <em>vpu</em> and <em>env</em> Genes of HIV-1 Can Adversely Impact Infectivity: A Dissertation Richards, Kathryn H. 12 May 2008 (has links) The Human Immunodeficiency Virus (HIV) is able to infect CD4+ T cells as well as macrophages. Macrophage-tropism has been linked to determinants in the envelope of HIV. These determinants allow envelopes to exploit low levels of CD4 for infection. Macrophages are an important reservoir of virus, especially during chronic infection, and are likely responsible for the bulk of virus produced after CD4+T cells have declined. Viral factors that may impact the ability to infect macrophages are worth studying because this cell type is so important in infection. It was previously reported that the macrophage-tropic primary isolate AD8 was vpu-independent. The molecular clone YU-2, derived from brain tissue without culture, was also reported to be macrophage-tropic despite having a mutation in the vpu start codon. It was therefore possible that vpu-independent envelopes could evolve in vivo. To examine this possibility, I constructed chimeras containing wild type or defective vpu start codons, and gp160 sequences from AD8, YU-2 or SF162 (a vpu-dependent control). I also used full length AD8 and YU-2 with wild type or defective vpu start codons. I infected macrophages with equal amounts of virus, and measured viral output over two weeks. Viruses with defective vpu start codons were released to lower levels compared to their wild type vpucounterparts. In contrast to previous reports, the AD8 envelope is not vpu-independent for replication in macrophages. The YU-2 envelope is also not vpu-independent. Macrophage-tropic envelopes from late stages of infection can be sensitive to antibodies that bind the CD4 binding site on gp120, implying that macrophage-tropic envelopes have more exposed CD4 binding sites. Neutralizing antibodies may act as modulators of macrophage-tropism over the course of infection. Using chimeras containing gp120 sequences derived from the PBMC of four HIV+patients, I examined the capacity for envelopes to infect macrophages. Three patients (MM1, 4, and 8) had macrophage-tropic envelopes before and after developing autologous neutralizing antibodies. Three patients (MM1, 4, and 23) developed heterologous antibodies against IIIB, an easily neutralized T-cell line adapted strain of HIV-1. This data indicates that macrophage-tropism in these patients is not modulated by the presence of neutralizing antibodies. The macrophage-tropism of envelopes tends to segregate depending on the tissue origin of the virus. Envelopes from two separate tissues from the same patient exhibit very different infectivity characteristics. The B33 envelope, from brain tissue, is very infectious and is macrophage-tropic, while the LN40 envelope, from lymph node tissue, is weakly infectious and is not macrophage-tropic. Replacing the entire gp41 of LN40 with that of B33 restores some infectivity to LN40. The cytoplasmic domain of gp41 contains many motifs important for assembly and infectivity. To examine which motifs are responsible for the weak infectivity of LN40, I made chimeras of gp41, as well as point mutations in gp41. The LN40 chimera containing the entire gp41 of B33 restored the most infectivity. Point mutations in the palmitoylation site, Pr55gagbinding region, and dileucine motif at the C-terminus also restored infectivity when combined. Determinants in the gp41 cytoplasmic domain are responsible for the weak infectivity of LN40; however, it is possible that there are contributing determinants in gp120, such as the ability to use low levels of CD4. Here, I examined how changes in the vpu and env genes of HIV-1 can impact infectivity, especially infectivity of macrophages. Changes that adversely impact the virus’ ability to infect macrophages may also impact the overall course of disease. However, the data here show that retaining the ability to infect, and replicate in, macrophages give HIV an advantage. I speculate that retaining the ability to infect macrophages gives the virus a reservoir for later in disease, when CD4+ T cells have been depleted, as well as way of avoiding neutralizing antibodies. This work further defines the importance of macrophages in HIV-1 infectivity and disease. HIV-1 HIV Infections Tropism Viral Envelope Proteins Macrophages Human Immunodeficiency Virus Proteins Viral Regulatory and Accessory Proteins Virus Replication Amino Acids, Peptides, and Proteins Cells Genetic Phenomena Hemic and Immune Systems Viruses
68	Investigating the Roles of NEDD4.2s and Nef in the Release and Replication of HIV-1: A Dissertation Weiss, Eric R. 13 September 2012 (has links) Replication of HIV-1 requires the assembly and release of mature and infectious viral particles. In order to accomplish this goal, HIV-1 has evolved multiple methods to interact with the host cell. HIV-1 recruits the host cell ESCRT machinery to facilitate the release of nascent viral particles from the host cell membrane. Recruitment of these cellular factors is dependent on the presence of short motifs in Gag referred to as Late-domains. Deletion or mutation of these domains results in substantial decrease in the release of infectious virions. However, previously published work has indicated that over-expression of the E3 ubiquitin ligase, NEDD4.2s is able to robustly rescue release of otherwise budding-defective HIV-1 particles. This rescue is specific to the NEDD4.2s isoform as related E3 ubiquitin ligases display no ability to rescue particle release. In addition, rescue of particle release is dependent on the presence of the partial C2 domain and a catalytically active HECT domain of NEDD4.2s. Here I provide evidence supporting the hypothesis that a partial C2 domain of NEDD4.2s constitutes a Gag interacting module capable of targeting the HECT domains of other E3 ubiquitin ligases to HIV-1 Gag. Also, by generating chimeras between HECT domains shown to form poly-ubiquitin chains linked through either K48 or K63 of ubiquitin, I demonstrate that the ability of NEDD4.2s to catalyze the formation of K63-polyubiquitin chains is required for its stimulation of HIV-1 L-domain mutant particle release. In addition, I present findings from on-going research into the role of the HIV-1 accessory protein Nef during viral replication using the culture T-cell line, MOLT3. My current findings indicate that downregulation of CD4 from the host cell membrane does not solely account for the dramatic dependence of HIV-1 replication on Nef expression in this system. In addition, I present evidence indicating that Nef proteins from diverse HIV-1 Groups and strains are capable of enhancing HIV-1 replication in this system. Analysis of a range of mutations in Nef known to impact interaction with cellular proteins suggest that the observed replication enhancement requires Nef targeting to the host cell membrane and may also require the ability to interact with select Src-kinases. Lastly, we find that the ability of Nef to enhance replication in this system is separate from any increase in viral particle infectivity, in agreement with current literature. Virus Replication Virus Release HIV-1 Ubiquitin-Protein Ligases nef Gene Products Human Immunodeficiency Virus Amino Acids, Peptides, and Proteins Cells Enzymes and Coenzymes Genetic Phenomena Immunology and Infectious Disease Microbiology Virology Viruses
69	Modelling genetic regulatory networks: a new model for circadian rhythms in Drosophila and investigation of genetic noise in a viral infection process Xie, Zhi January 2007 (has links) In spite of remarkable progress in molecular biology, our understanding of the dynamics and functions of intra- and inter-cellular biological networks has been hampered by their complexity. Kinetics modelling, an important type of mathematical modelling, provides a rigorous and reliable way to reveal the complexity of biological networks. In this thesis, two genetic regulatory networks have been investigated via kinetic models. In the first part of the study, a model is developed to represent the transcriptional regulatory network essential for the circadian rhythms in Drosophila. The model incorporates the transcriptional feedback loops revealed so far in the network of the circadian clock (PER/TIM and VRI/PDP1 loops). Conventional Hill functions are not used to describe the regulation of genes, instead the explicit reactions of binding and unbinding processes of transcription factors to promoters are modelled. The model is described by a set of ordinary differential equations and the parameters are estimated from the in vitro experimental data of the clocks' components. The simulation results show that the model reproduces sustained circadian oscillations in mRNA and protein concentrations that are in agreement with experimental observations. It also simulates the entrainment by light-dark cycles, the disappearance of the rhythmicity in constant light and the shape of phase response curves resembling that of experimental results. The model is robust over a wide range of parameter variations. In addition, the simulated E-box mutation, perS and perL mutants are similar to that observed in the experiments. The deficiency between the simulated mRNA levels and experimental observations in per01, tim01 and clkJrk mutants suggests some differences in the model from reality. Finally, a possible function of VRI/PDP1 loops is proposed to increase the robustness of the clock. In the second part of the study, the sources of intrinsic noise and the influence of extrinsic noise are investigated on an intracellular viral infection system. The contribution of the intrinsic noise from each reaction is measured by means of a special form of stochastic differential equation, the chemical Langevin equation. The intrinsic noise of the system is the linear sum of the noise in each of the reactions. The intrinsic noise arises mainly from the degradation of mRNA and the transcription processes. Then, the effects of extrinsic noise are studied by means of a general form of stochastic differential equation. It is found that the noise of the viral components grows logarithmically with increasing noise intensities. The system is most susceptible to noise in the virus assembly process. A high level of noise in this process can even inhibit the replication of the viruses. In summary, the success of this thesis demonstrates the usefulness of models for interpreting experimental data, developing hypotheses, as well as for understanding the design principles of genetic regulatory networks. systems biology genetic regulatory networks mathematical molecular modelling kinetic modelling Hill function stochastic modelling stochastic differential equations chemical Langevin equation oscillations circadian clock circadian rhythms Drosophila intrinsic noise extrinsic noise viral infection virus replication
70	Recruitment of the complete hTREX complex is required for Kaposi's sarcoma-associated herpesvirus intronless mRNA nuclear export and virus replication Boyne, J. R., Colgan, K. J., Whitehouse, A. January 2008 (has links) A cellular pre-mRNA undergoes various post-transcriptional processing events, including capping, splicing and polyadenylation prior to nuclear export. Splicing is particularly important for mRNA nuclear export as two distinct multi-protein complexes, known as human TREX (hTREX) and the exon-junction complex (EJC), are recruited to the mRNA in a splicing-dependent manner. In contrast, a number of Kaposi's sarcoma-associated herpesvirus (KSHV) lytic mRNAs lack introns and are exported by the virus-encoded ORF57 protein. Herein we show that ORF57 binds to intronless viral mRNAs and functions to recruit the complete hTREX complex, but not the EJC, in order assemble an export component viral ribonucleoprotein particle (vRNP). The formation of this vRNP is mediated by a direct interaction between ORF57 and the hTREX export adapter protein, Aly. Aly in turn interacts directly with the DEAD-box protein UAP56, which functions as a bridge to recruit the remaining hTREX proteins to the complex. Moreover, we show that a point mutation in ORF57 which disrupts the ORF57-Aly interaction leads to a failure in the ORF57-mediated recruitment of the entire hTREX complex to the intronless viral mRNA and inhibits the mRNAs subsequent nuclear export and virus replication. Furthermore, we have utilised a trans-dominant Aly mutant to prevent the assembly of the complete ORF57-hTREX complex; this results in a vRNP consisting of viral mRNA bound to ORF57, Aly and the nuclear export factor, TAP. Strikingly, although both the export adapter Aly and the export factor TAP were present on the viral mRNP, a dramatic decrease in intronless viral mRNA export and virus replication was observed in the absence of the remaining hTREX components (UAP56 and hTHO-complex). Together, these data provide the first direct evidence that the complete hTREX complex is essential for the export of KSHV intronless mRNAs and infectious virus production. Active transport; Cell nucleus Metabolism DEAD-box RNA Helicases Exodeoxyribonucleases Herpesvirus 8; Human; Physiology Humans Multiprotein complexes Nuclear cap-binding protein complex Nuclear export signals Nuclear proteins Phosphoproteins RNA Processing; Post-transcriptional RNA Transport Messenger Viral RNA-binding proteins Transcription factors Viral proteins Virus replication REF 2014

Search results